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Singlet Oxygen Generation and Triplet Excited State Spectra of Brominated BODIPY Xian-Fu Zhang, and Xudong Yang J. Phys. Chem. B, Just Accepted Manuscript • DOI: 10.1021/jp4013812 • Publication Date (Web): 10 Apr 2013 Downloaded from http://pubs.acs.org on April 16, 2013
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Singlet Oxygen Generation and Triplet Excited State Spectra of Brominated BODIPY
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Singlet Oxygen Generation and Triplet Excited State Spectra of Brominated BODIPY
Xian-Fu Zhang*,†,‡ and Xudong Yang† †
Chemistry Department & Center of Instrumental Analysis, Hebei Normal University of
Science and Technology, Qinhuangdao, Hebei Province, 066004 China ‡
MPC Technologies, Hamilton, Ontario, Canada L8S 3H4
*
To whom correspondence should be addressed
E-mail:
[email protected]. Fax: 86 3358357040. Tel: 86 3358357040
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ABSTRACT: The excited triplet-, singlet- and ground-state properties, as well as singlet oxygen generation capability of four brominated BODIPY dyes were measured in toluene with laser flash photolysis, fluorescence spectroscopy, time-correlated single photon counting and absorption spectroscopy. The triplet-triplet (T1-Tn) absorption spectra were identified for four dyes 1B, 2B, 4B and 6B substituted with one, two, four and six Br atoms, respectively. The triplet quantum yield (ΦT) of a usual BODIPY dye is negligible and has rarely been studied. So is the case for the parent compound 0B (8-phenyl borondipyrromethene) in which no Br atom is present. The substitution of the first Br atom into π−ring of BODIPY allowed a dramatic increase of ΦT from 0.0 of 0B to 0.39 for 1B. The further addition of Br number increased ΦT to 0.46, 0.50 and 0.66 for 2B, 4B and 6B, respectively. The triplet lifetimes τT are also fairly long, which is 43, 39, 36, and 26 μs for 1B, 2B, 4B and 6B, respectively. The brominated BODIPY dyes are therefore efficient singlet oxygen photosensitizers with the formation quantum yield of 0.39, 0.45, 0.49 and 0.64 for 1B, 2B, 4B and 6B, respectively. The result indicates their potential application in photodynamic therapy of cancer. The fluorescence properties of the dyes were also measured. Keywords:
BODIPY, singlet oxygen, triplet state, fluorescence, bromination
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■ INTRODUCTION Boron-dipyrromethene complexes (BODIPY) are well known fluorophores,1,2 which are used as laser dyes,3-5 labeling reagents,6 fluorescent switches,7 chemosensors8 and OLEDs.9 These applications are based on their photophysics of the lowest lying excited singlet state (S1), mainly involving S1↔S0 electronic transitions (S0 is the ground state). New applications based on their T1 (the lowest lying excited triplet state) photophysics have also appeared recently, including singlet oxygen photosensitizers for PDT10-12 (photodynamic therapy of cancer) and NIR photon upconversion.13-15 These dyes generally show intense and narrow absorption and fluorescence bands in the visible region, high fluorescence quantum yields, as well as good thermal and photochemical stability.1,2 BODIPY dyes usually exhibit negligible efficiency of T1 formation due to the high fluorescence quantum yields. T1 is the key intermediate that leads to the formation of singlet oxygen (1Δg) by energy transfer process: T1 + O2 → S0 + O2 (1Δg), O2 (1Δg) is the reactive oxygen species that plays the main role to damage tumor tissues in PDT.10 Due to the very low efficiency of T1 formation, heavy atoms (such as Br, I) are often incorporated into the BODIPY structure to enhance the spin–orbit coupling.10,12 The in vitro or in vivo tests showed that the halogenated BODIPYs could effectively kill tumor cells.11,16 However, there have been no associated study focusing on the triplet T1 properties for these BODIPY dyes, such as the effect of the type, position and number of halogen atoms. Also the triplet properties for usual BODIPY dyes are rarely studied due to the negligible T1 formation efficiency, although the synthesis and fluorescence properties of BODIPY have been
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extensively carried out by many researchers.1,2,16-18 In this study we report the effect of bromine substitution on the triplet state and singlet oxygen generation of BODIPY dyes (Figure 1).
Figure 1. The chemical structure of brominated BODIPYs
■ EXPERIMENTAL SECTION Chemicals. The synthesis and characterization for these compounds have been described before.16 Toluene is of analytical grade and used after redistillation. Solution preparation. A dye was first dissolved in toluene to make a stock concentrated solution ca. 1 mM. Then, the dye was diluted in another vial to accommodate the absorbance at the instruments requirements. Absorption measurements. Ground-state UV-vis absorption spectra were recorded on a StellarNet BLACK Comet C-SR diode array miniature spectrophotometer connected to deuterium and halogen lamp by Optical fiber using 1 cm matched quartz cuvettes at room temperature. Fluorescence measurements. Fluorescence spectra were recorded using Edinburgh Instruments FLS920 fluorospectrometer, with 2 nm slits for excitation at 480 nm and emission from 490 to 750 nm. All spectra were corrected for the sensitivity of the photo-multiplier tube. The fluorescence quantum yield (Φf) was computed by using
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Φ f = Φ 0f ⋅
Fs A 0 ns2 , ⋅ F0 A s n02
Eq. (1)
in which F is the integrated fluorescence intensity, A is the absorbance at excitation wavelength, n is the refractive index of the solvent used, the subscript 0 stands for a reference compound and s represents samples. Rhodamine 6G in ethanol was used as the reference (Φf =0.95).19 The sample and reference solutions were prepared with the same absorbance (Ai) at the excitation wavelength (near 0.090 in a 1 cm quartz cell). All solutions were air saturated. Fluorescence lifetime of S1 state was measured by time-correlated single photon counting method (Edinburgh FLS920 spectrophotometer) with excitation at 379 nm by a portable diode laser (69 ps FWHM) and emission was monitored at the peak maximum. The lifetime values were computed by the F900 software coming with the instrument. Laser flash photolysis. Nanosecond transient absorption measurements were obtained using LP920 (Edinburgh Instruments Ltd.). The excitation source was a Qswitched Nd/YAG laser (BRIO) of 4 ns full width at half maximum with third harmonic (355 nm) generation. The 355 nm beam was directed onto one side of a 1 cm square silica cell containing the sample (absorbance around 0.2) after bubbing Ar gas during 20 min. The transient transmission variations were monitored at right angles to the excitation in a crossbeam arrangement using a 450W xenon flash lamp, a monochromator, a photomultiplier and a digitized oscilloscope interfaced with a desktop computer. The power of the incident 355 nm laser pulse in the sample was about 5mJ. The triplet quantum yield ΦT was obtained by comparing the ΔAT of the optically matched sample solution at peak maximum in a 1 cm cuvettes to that of the reference using the equation 20:
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Φ T =Φ
ZnPc T
ΔA T Δε TZnPc ⋅ ⋅ , ΔA TZnPc Δε T
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Eq. (2)
Where the superscript represents the reference, ΔAT is the absorbance of the triplet transient difference absorption spectrum at the selected wavelength, and ΔεT is the triplet state molar absorption coefficient, which is obtained by Eq. (3).
Δε T = ε S
ΔAT ΔAS
Eq. (3)
Where ΔAS and ΔAT are the absorbance change of the triplet transient difference absorption spectrum at the minimum of the bleaching band and the maximum of the positive band, respectively, and εS is the ground-state molar absorption coefficient at the UV-vis absorption band maximum. Both ΔAS and ΔAT were obtained from the triplet transient difference absorption spectra. Singlet oxygen generation. Singlet oxygen quantum yield (ΦΔ) determinations were carried out using the chemical trapping method
21
. Typically, a 3 ml portion of the
respective PS solutions that contained diphenylisobenzofuran (DPBF) was irradiated at 510 nm in air saturated toluene. ΦΔ value was obtained by the relative method using methylene blue as the reference (Eq. 4): Φ Δ =Φ Δref
k Iaref , k ref Ia
Eq. (4)
where Φ Δref is the singlet oxygen quantum yield for the standard (0.79),22 k and kref are the DPBF photo-bleaching rate constants in the presence of the respective samples and standard, respectively; Ia and Iaref are the rates of light absorption at the irradiation wavelength of 510 nm by the samples and standard, respectively. Their ratio can be
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obtained by Eq. (5). ref
Iaref 1-10-A670 , = Ia 1-10-A670
Eq. (5)
To avoid chain reactions induced by DPBF in the presence of singlet oxygen, the concentration of DPBF was lowered to ∼ 3×10-5 mol dm-3. A solution of sensitizer (absorbance ~0.80 at the irradiation wavelength) that contained DPBF was prepared in the dark and irradiated in the 510 nm. DPBF degradation was monitored by UV-vis absorption spectrum. The error in the determination of ΦΔ was ~10% (determined from several ΦΔ values).
■ RESULTS AND DISCUSSION The triplet state properties are summarized in Table 1, together with ground state absorption and fluorescence parameters. In the absence of Br substitution, no triplet absorption and singlet oxygen photooxidation was found. Brominated BODIPYs, however, hold remarkable ΦT and ΦΔ value from 39-66%. Both the position and number of Br atoms exhibit significant effect. The heavy atom effect, on the other hand, does not lead to 100% efficiency for ΦT even after the BODIPY core is fully halogenated by six Br atoms. The details are explained following.
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Table 1 The absorption, triplet state and fluorescence properties of brominated BODIPYs in toluene*** abs T −T λmax , nm λmax , nm
0B 1B 2B 4B 6B ***
501 521 540 559 556
420 420, 435 435, 450 460
τT, μs ΦT ΦΔ 43 39 36 26
0 0.39 0.46 0.50 0.66
0 0.39 0.45 0.49 0.64
em λmax , nm Φf
522 543 565 576 569
τf, ns
χ2
0.044 0.44(99%), 5.13 1.00 0.071 0.73(98.5%), 1.75 0.99 0.053 0.76(95%), 2.11 1.02 0.065 0.25(2%), 3.47 1.00 0.014 0.82(83%), 2.54 1.05
abs T −T Experimental error for Φf, ΦT and ΦΔ is about 10%. λmax :absorption maximum. λabs :T1-Tn
absorption maximum. τT: triplet lifetime. ΦT: quantum yield for triplet formation. ΦΔ: quantum yield for singlet oxygen formation.
em λmax :
emission maximum. Φf: fluorescence quantum yield. τf: fluorescence
2
lifetime. χ : chi square values for τf fitting.
Ground state absorption spectra. Figure 2 shows the normalized absorption
spectra of brominated BODIPYS in toluene. There are three types of bromine atoms on BODIPY core π−system (Figure 1): (i) 2,6-Br in 1B and 2B, (ii) 3,5-Br in 4B and (iii) 1,7-Br in 6B. The shape of the absorption spectra remains very similar to 0B upon the addition of more Br atoms at different positions in 1B to 6B. The absorption maximum, however, was changed by the Br presence. Br atoms in 2,6-position have the most remarkable effect, while that in 1,7-position show the least influence. For example, the occurrence of 2-Br in 1B caused a 20 nm red-shift relative to 0B, and one more 6-Br in 2B gave a 19 nm further red-shift relative to 1B, each Br made
the same contribution. Two additional Br atoms on 3,5-position of 4B, however, exhibited a total of 19 nm further red-shift relative to 2B, that is 10 nm on average for each Br atom. This 10 nm red-shift is consistent with that the Br substitution shows on the electronic absorption of aromatic compounds. On the other hand, 1,7-Br substitutions cause a slight blue shift which is due to their steric effect, since the large Br atoms at 1,7
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position cause the rotational hindrance of the phenyl and BODIPY core. The similar blue shift was also observed for 2,2',6,6'-tetramethylbiphenyl relative to biphenyl.23
Figure 2. Normalized absorption spectra of brominated BODIPYS in toluene.
Triplet-Triplet (T1-Tn) absorption. Upon laser flash photolysis (Nd:YAG; 355
nm; 4ns), both deaerated and air-saturated 0B solutions in toluene produced no observable transient absorption in the visible region. The brominated BODIPYs 1B to 6B, however, showed similar transient absorption spectra (TAS). All TAS have a positive band with peak maximum within 420-460 nm and a negative band at 460-550 nm (Figure 3). The positive band occurred immediately only with the presence of laser excitation of the dyes. It then decayed after the laser excitation was shut off. Therefore the positive absorption relates to an excited state of BODIPYs. It is T1 absorption as several reasons discussed hereafter. It is certainly not S1, since the decay lifetime of the positive band is in the order of tens of microsecond (Table 1), while the fluorescence lifetime is shorter than one nanosecond (Table 1). The shape and position of the negative band for each dye matches the corresponding S0 absorption (Figure 2). The negative band was increased concurrently with the decay of the positive band. The positive bands are
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separated from the negative bands with well defined isosbestic points, indicating a transformation exists between only two species T1 and S0. Therefore both the rise of the negative bands and the decay of the positive bands are due to: T1 → S0. In other words, the decay of T1 led to the formation of S0. The following facts also indicate that the positive bands are due to triplet-triplet (T1-Tn) absorption. 1) Efficient molecular oxygen quenching on τT. Figure 4 shows the first-order decay kinetics of the transient species for 6B in the absence of oxygen. From the decay of these dyes, the lifetimes ( τ 0T ) were computed to be 43, 39, 36 and 26 μs for 1B, 2B, 4B and 6B
respectively. It can be emphasized that these lifetime values in the microsecond scale also correspond to T1-Tn absorption. In the air-saturated solutions (e.g. inset of Figure 4), however, τT was dramatically reduced to 0.41, 0.33, 0.32, 0.40 μs for 1B, 2B, 4B and 6B, respectively; in the mean time the shape of the transient absorption spectra remained the same. This suggests that a very fast physical quenching process exists. The quenching rate constant kq can be evaluated by Eq. (6) τ 0T /τT =1+kq τ 0T [O2],
Eq. (6)
from which the kq value is 1.33×109, 1.67×109, 1.72×109, and 1.34×109 M-1 s-1 for 1B, 2B, 4B and 6B, respectively taking [O2] as 1.8 mmol/L in air-saturated solution.24 The
value of kq is in the order of diffusion rate constant, such a fast process means the quenching is spin-allowed, consistent with the triplet-triplet energy transfer from T1 of brominated BODIPY to molecular oxygen (also triplet state): T1 (BODIPY) + T0 (O2) → S0 (BODIPY) + S1 [1O2 (1Δg)]
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2) The heavy atom effect also indicates the positive band is due to T1 absorption. With increasing the number of Br atoms on BODIPY core from 1B to 6B, τT value is decreased while ΦT is increased (Table 1). The more heavy atoms, the faster the intersystem crossing (ISC) proceeds for both a) S1 → T1 and b) T1 → S0.
The
enhancement of the former process a) increases ΦT, while the promotion of process b) shortens the τT.
Figure 3. Transient absorption spectra of brominated BODIPYs in degassed toluene with
355 nm laser excitation
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The increase of Br atom numbers also led to the gradual red-shift of T1-Tn absorption (Table 1), even in the case of 6B. For 6B, its S0-S1 absorption is blue-shift relative to 4B. This suggests that 3,5-Br substitution exhibits different effects on S0-S1 and T1-Tn electronic transition, respectively.
Figure 4. The decay of T1-Tn absorption at 460 nm in argon-saturated toluene of 6B with
excitation by 355 nm laser. Inset: The decay of T1-Tn absorption at 470 nm and recovery of ground state absorption at 510 nm in air-saturated toluene of 6B with excitation by 355 nm laser.
Singlet oxygen formation. Figure 5 shows the time profiles of the absorption
spectra with irradiation at 510 nm in air-saturated toluene, in which 1B was the photosensitizer while DPBF was the substrate. DPBF absorbs with peak maximum at 410 nm and shows no absorption at 510 nm. The 510 nm light was absorbed only by the brominated BODIPYs.
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Figure 5. Top: The time evolution of the absorption spectra in 1B (15 μM)
photosensitized system containing 22 μM DPBF in toluene, with irradiation at 510 nm. Bottom: The plot of DPBF absorbance at 410 nm against time, and the linear fitting.
The absorption bands of the sensitizer 1B were not changed by the light illumination. The DPBF absorption, on the other hand, was decreased with irradiation in the presence of the sensitizer. Without any one of the sensitizer, light and oxygen, DPBF was not subjected to the change. The results confirm that the degradation of DPBF is indeed due to the oxidation by singlet oxygen through the following mechanism. S0 (BODIPY) + hν (510 nm) → S1 (BODIPY) S1 (BODIPY) → T1 (BODIPY) T1 (BODIPY) + O2 → S0 (BODIPY) + 1O2 DPBF + 1O2 → product DBB (Figure 6).
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Figure 6. DPBF photooxidation product
Since the product shows no absorption in the visible range, the concentration decrease of DPBF was monitored using UV–vis spectrometer, the absorbance at 410 nm of DPBF (absorption maximum) was recorded and plotted against irradiation time for quantitative kinetic analysis (Figure 5 bottom). The plot can be approximated by a linear fitting, indicating it is pseudo zero-order kinetics. The slope k of the line is the representative of the reaction rate constants. The singlet oxygen quantum yields (ΦΔ) were then calculated as described in the experimental section. The ΦΔ values for the dyes are 0.00, 0.39, 0.45, 0.49 and 0.64, respectively. ΦΔ is increased with the increase of Br atom number, consistent with the change of ΦT. Fluorescence properties. The steady state fluorescence spectra and fluorescence
quantum yield (Φf) in dichloromethane had been reported before.16 We measured here τf (Table 1) in toluene in addition to the steady state fluorescence spectra (Figure 7) and Φf (Table 1). The shape of all fluorescence spectra is similar but the emission maximum is red-shifted by the increase of Br number except for 6B. The change tendency is consistent with the effect of Br substitution on the absorption maximum. A mirrorsymmetry holds between the excitation and emission spectra (e. g. 6B in Figure 7 bottom) for each compound.
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Figure 7. Left: the fluorescence spectra of the brominated BODIPYs (10 μM) in toluene
with excitation at 480 nm. Right: The normalized excitation and emission spectra for 6B.
All these dyes show a small value of Φf, mostly consistent with the previous report.16 Figure 8 shows the fluorescence decay curves. The fluorescence decays are biexponential (Figure 8). An additional long-lived component appeared in these compounds suggests that the presence of complicated photophysical processes. In toluene, both Φf and τf do not show the monotonical decrease with the increase of Br number, due to the presence of several different effects caused by the Br substitution. The bromination causes at least four different effects as following. 1) Heavy atom effect (HAE) that can enhance ISC, hence decrease Φf and shorten τf. HAE is solvent independent. It is generally established that HAE on fluorescence is significant only when Φf of the parent compound is sufficiently high. In this case, the
Φf of the parent compound 0B is already very low (0.044, 0.036 in toluene and DMF respectively), and the lifetime (main component) is also short (0.44 ns), so the influence of HAE on Φf of the dyes will not be obvious, which is supported by the
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data in Table 1 measured in toluene. On the other hand, the significant heavy atom effect on ΦT by the bromination occurs since ΦT of the parent compound 0B is 0.0. 2) The bromination significantly increases the mass of BODIPY core, so that the vibration and rotation rate of BODIPY core along the σ bond linked to the phenyl moiety is remarkably slowed down. Note that the vibration and rotation are the main paths that deactivate S1 state of the BODIPY core. In the absence of the phenyl, Φf and τf is 0.80 and 5.2 ns,2 respectively. The value is decreased to 0.044 and 0.44 ns, respectively when the phenyl is present. Hence kic (the rate of internal conversion) is increased from 0.38×108 to 0.22×1010 s-1 by the vibration and rotation of the phenyl. The mass ratio of the phenyl over the BODIPY core (containing n Br atoms) is 77:(167+80n), which shows a big increase from 1:2.17 to 1:3.21, 1:4.24, 1:6.32 and 1:8.4 for 0B, 1B, 2B, 4B and 6B, respectively. The slowing down of the vibration and rotation rate will increase the value of Φf and τf. 3) Bromination lowers also the oxidation potential of the linked BODIPY π−system as we have shown in a previous report,25 so that intramolecular photoinduced electron transfer (PET) can occur from S1 of the core π−system.25 BF2 is strongly electron withdrawing and can act as a good electron acceptor (Figure 9). PET competes with emission and ISC to lower Φf and τf. However, PET is strongly solvent dependent and expected to be very slow in toluene, which is a solvent with low polarity. We then measured the Φf and τf in ethanol and DMF, both are polar solvents. For example, the main component of τf for 1B is 0.73, 0.51 and 0.42 ns in toluene, ethanol and DMF respectively; the main component of τf for 2B is 0.76, 0.60 and 0.46 ns in toluene, ethanol and DMF respectively; and the main component of τf for
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6B is 0.82, 0.63 and 0.31 ns in toluene, ethanol and DMF respectively. Φf shows the
same solvent effect. In each case, the higher the polarity, the lower the value for Φf and τf, this is consistent with the expected for PET. This PET from S1 has no effect on
ΦT. 4) Steric effect is particularly important for 6B, in which the rotation of the phenyl is hindered by the Br atoms at position 1 and 7. This hindrance also disfavors PET.
Figure 8. Top: the decay traces of the fluorescence of the brominated BODIPYs (10 μM)
in toluene with excitation by 379 laser (69 ps). The emission was monitored at the emission maximum of each dye. Middle and Bottom: The fitting residue for 1B (monoexponential) and 6B (biexponential).
Figure 9. Photoinduced electron transfer in a brominated BODIPY
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Due to the coexistence of four different effects caused by the bromination, the overall result to a specific dye can be different from one to the other.
■ CONCLUSION The transient absorption in μs scale for the brominated dyes was shown to be due to T1-Tn triplet-triplet absorption, which has rarely been studied. τT and ΦT were then calculated based on the T1-Tn absorption. Except for 1,7-Br atoms, the other bromination cause the red-shift of S0 absorption, S1 fluorescence and T1-Tn absorption. All the bromination led to the increase of ΦT, ΦΔ and shortening of τT. τT is still fairly long in the order of tens of microseconds, which allow the efficient generation of singlet oxygen with ΦΔ close to its ΦT in each case. ΦT and ΦΔ of the dyes containing Br atoms are in the range from 40 to 65%, which suggests the brominated BODIPYs are potential photosensitizers. In contrast to the remarkable heavy atom effect on ΦT, the bromination has smaller but complexed influence on Φf and τf due to the very low fluorescence efficiency of the parent compound, the slowing down of vibration and rotation rate of BODIPY core, the change of oxidation potential of the BODIPY and the hindrance to the rotation of the phenyl.
■ AUTHOR INFORMATION Corresponding Author
*E-mail:
[email protected].
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■ ACKNOWLEDGEMENTS This work has been supported partially by Hebei Provincial Science Foundation (Contract B2010001518) and HBUST (Contract CXTD2012-05). We thank Prof. Lijuan Jiao of Anhui Normal University for kindly supplying the borminated BODIPYs.
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